Pre-Fetch Data and Pre-Fetch Data Relative

ABSTRACT

A prefetch data machine instruction having an M field performs a function on a cache line of data specifying an address of an operand. The operation comprises either prefetching a cache line of data from memory to a cache or reducing the access ownership of store and fetch or fetch only of the cache line in the cache or a combination thereof. The address of the operand is either based on a register value or the program counter value pointing to the prefetch data machine instruction.

TRADEMARKS

IBM® is a registered trademark of International Business MachinesCorporation, Armonk, N.Y., U.S.A. Other names used herein may beregistered trademarks, trademarks or product names of InternationalBusiness Machines Corporation or other companies.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to computer systems and in particular to systemswhich allow software pre-fetch data from memory and alter cache state.

2. Description of Background

In a multiprocessing system where a consistent memory usage model isrequired, memory usage among different processors is managed using cachecoherency ownership schemes. These schemes usually involve variousownership states to a cache line. Preferably, these states includeread-only (commonly known as shared or fetch access ownership), andexclusive (where a certain processor has the sole and explicit updaterights to the cache line, sometimes known as store access ownership).

For one such protocol used for a strongly-ordered memory consistencymodel, as in IBM's z/Architecture® implemented by IBM System zprocessors, when a processor is requesting rights to update a line, e.g.when it is executing a “Store” instruction, it will check its localcache (L1) for the line's ownership state. If the processor finds outthat the line is either currently shared or is not in its cache at all,it will then send an “exclusive ownership request” to the storagecontroller (SC), which serves as a central coherency manager. The IBM®z/Arehitccture® is described in the z/Architecture Principles ofOperation SA22-7832-05 published April, 2007 by IBM and is incorporatedby reference herein in its entirety.

US Patent Application Docket No POU820070334 “METHOD AND APPARATUS FORACTIVE SOFTWARE DISOWN OF CACHE LINES EXCLUSIVE RIGHTS” by IBM filedconcurrently with the present application is incorporated by referenceherein in its entirety.

U.S. Pat. No. 5,623,632 “System and method for improving multilevelcache performance in a multiprocessing system” from IBM, filed May 15,1995, incorporated herein by reference, describes a multiprocessorsystem having a plurality of bus devices coupled to a storage device viaa bus, wherein the plurality of bus devices have a snoop capability, andwherein the plurality of bus devices have first and second caches, andwherein the plurality of bus devices utilize a modified MESI datacoherency protocol. The system provides for reading of a data portionfrom the storage device into one of the plurality of bus devices,wherein the first cache associated with the one of the plurality of busdevices associates a special exclusive state with the data portion, andwherein the second cache associated with the one of the plurality of busdevices associates an exclusive state with the data portion. A busdevice initiating, a write-back operation with respect to the dataportion, determining if there are any pending snoops in the secondcache, and changing the special exclusive state to a modified state ifthere are no pending snoops in the second cache. If there is a pendingsnoop in the second cache, a comparing of addresses of the pending snoopand the data portion is performed. The special exclusive state ischanged to a modified state if the addresses are different. The specialexclusive state indicates that a data portion is held in the primarycache in a shared state and that the data portion is held in thesecondary in an exclusive state.

In one embodiment, a storage controller (SC) tracks which processor, ifany, currently owns a line exclusively. If deemed necessary, the storagecontroller (SC) will then send a “Cross interrogate” (XI) or “ownershipchange” request to another processor which currently owns that line torelease its exclusive rights. In this embodiment, a cross interrogate(XI) is referred to as “cross invalidate” since the action mayinvalidate the line in the other processor cache. Once the currentowning processor has responded to the XI and responded that theexclusive ownership is released, the requesting processor will then begiven exclusive update rights to the line requested.

In a large SMP (Symmetric Multi-Processing) system, it is common thatvarious processes running on different processors update the same cachelines, but at different times. When a line is updated by one process,and then another process starts up, updating the same line by the oneprocess wilt encounter delays required for XI acknowledgement whileexchanging exclusive ownerships from one processor to another. Thesedelays amount to a significant performance degradation as number ofprocesses goes up that reuse the same cache lines.

A program application would, of course, know whether a particular dataobject (cache line) it had stored to would be needed again in the nearfuture by the program. Such a program may desire to release the cacheline associated with the store in order to improve performance in amulti-processor environment, however prior to the present invention,this was not possible.

SUMMARY OF THE INVENTION

The shortcomings of the prior art are overcome and additional advantagesare provided through the provision of a new instruction or instructionvariation that allows software to indicate to hardware that its storagemodification to a particular cache line is done, and that it will not bedoing any further modification for the time being.

This invention provides prefetch data machine instructions to prefetchdata to the cache from memory and/or to signal the CPU hardware that theprogram is done with a particular cache line, and will not be doing anyfurther modification for a long time, allowing the system to alter itscache state according to information provided by executing theinstruction. With this indication, the processor can then activelyrelease its exclusive ownership by updating its line ownership fromexclusive to read-only (or shared) in its own cache directory and in thestorage controller (SC). By actively giving up its exclusive rights, thefirst processor allows a subsequent request from another processor toimmediately be given exclusive ownership to that cache line withoutwaiting on any processor's explicit cross invalidate acknowledgement.This invention is supported by the described hardware design needed toprovide this support.

After receiving such indication, a microprocessor can activelyrelinquish its exclusive ownership to a cache line, and preemptivelyupdate the ownership status in the storage controller to “shared”, thusremoving delays due to XIs that would have otherwise been encounteredshould another processor request an exclusive ownership to the cacheline.

The actual microprocessor implementation involves processing theinstruction, and new interface to communicate the “demote” request tothe storage controller. It is also important to provide necessaryinterlock to prevent a premature launch of the “demote” request. For usein a microprocessor design with a private L2, a design is described toensure all prior committed storage updates are sent and are received inthe storage controller before the “demote” request is sent.

It is therefore an feature of the invention to provide a method, systemand program product for executing a prefetch data machine instructionfor a processor having a cache wherein the processor fetches theprefetch data machine instruction in a program, the data prefetchmachine instruction comprising an opcode field, wherein the cache cachescache lines of memory information. The processor executing the fetcheddata prefetch machine instruction, the execution comprising determining,an address of an operand in memory; and performing a determined cacheaction on a cache line, the cache line associated with the determinedaddress of the operand in memory, the cache action consisting ofresponsive to the determined cache action being an access ownershipaction, changing access ownership of a line of data in the cache, theaccess ownership comprising any one of store access ownership, fetchaccess ownership, modified access ownership, owned access ownership,exclusive access ownership, shared access ownership or invalid accessownership.

It is a further feature of the invention to execute the instructionwherein said cache line is resident in a cache of a processor executingthe instruction, said cache action consisting of any one of reducing theaccess ownership from store access ownership to fetch access ownership,or reducing the access ownership from fetch access ownership to noaccess ownership.

It is another aspect of the invention to execute the instruction whereinthe data prefetch machine instruction further comprises an M field andsecond operand information, wherein the function of the data prefetchmachine instruction further comprises: interpreting the M field todetermine the cache action to be performed; determining from said secondoperand information, the address of the operand in memory; and whereinthe cache action further consisting of: responsive to the determinedcache action being a prefetch action, prefetching said operand in memoryinto a line of a cache, the cache associated with a processor executingthe instruction.

Additional features and advantages are realized through the techniquesof the present invention. Other embodiments and aspects of the inventionare described in detail herein and are considered a part of the claimedinvention. For a better understanding of the invention with advantagesand features, refer to the description and to the drawings.

As a result of the summarized invention, technically we have achieved asolution which reduces the overhead of cache line sharing by multipleprocesses across a large SMP system that contains writeable data. Theoverall system wide performance can then be improved.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter which is regarded as the invention is particularlypointed out and distinctly claimed in the accompanying claims. Theforegoing and other objects, features, and advantages of the inventionare apparent from the following detailed description taken inconjunction with the accompanying drawings in which:

FIG. 1 illustrates an initial state X where processor CPy owns line Aexclusive;

FIG. 2 illustrates what happens when processor CPx needs line Aexclusive after an initial state X;

FIG. 3 illustrates CPy executes a demote to line A after an initialstate X;

FIG. 4 illustrates what happens when processor CPx needs line Aexclusive after die demote process;

FIG. 5 illustrates a demote process for a different system design havingprivate L2 cache;

FIG. 6 illustrates a typical processor that is executing the demoteinstruction

FIG. 7 depicts a Host computer system of the prior art;

FIG. 8 depicts an emulated Host computer system of the prior art;

FIG. 9 illustrates an example format of Prefetch Data instructions; and

FIG. 10 illustrates an example flow depicting the function of theinvention.

The detailed description herein explains preferred embodiments of theinvention, together with advantages and features, by way of example withreference to the drawings.

DETAILED DESCRIPTION OF THE INVENTION

To allow software to indicate to hardware that a line is no longerrequired for further storage update, an instruction can be provided,with a way to indicate the logical address, as suited to a specificarchitecture. This is done with a new opcode or a new variation of anexisting cache management instruction using unused fields orcode-points. This specific instruction is likely expected to be used indevice drivers, operating system code or any application that usescommon parameter blocks or semaphore blocks.

The intention of this provision is that the software code will treatthis as a “done with store to this line” instruction, herein simplycalled a “demote” instruction (which may be embodied in a “PREFETCHDATA” instruction described herein). Preferably, the instruction is usedfor lines that contain highly utilized data across various processesthat are executing in different processors and most likely at differenttimes.

One typical software example comprises the management of a cache linethat contains various semaphore locks needed for multiprocessorhandling. The effect of the software using this provision will be toobtain or release a software lock managed in a cache line, and thendemote the line actively. By releasing the line actively, otherprocesses can proceed quicker to either obtain or release the same lockor other locks managed within the same cache line in their respectivecaches.

An important thing is that the software application knows that this isthe last point of update until some period of time later. If thesoftware requires an update to the line soon sifter a “demote” it wouldinstead be bad for performance, since then the processor will take timeto regain the exclusive rights.

One example embodiment is implemented in a computer system with a cachehierarchy as illustrated in FIG. 1. FIG. 1, like subsequent FIGS. 2-5,illustrates a bi-nodal system where the Storage Controller (SC) is madeup of 2 different physical node controllers SC0 101 and SC1 102, eachhaving 3 processors 103-108 attached.

FIG. 1 indicates a typical initial state where processor 103 (CPy)already owns the exclusive rights to a cache line A. FIG. 2 illustratesthat when processor 107 (CPx) requests to have exclusive rights to thesame cache line A, (e.g. when it is executing a “Store” instruction andneeds store access, for example) while processing a storage updateinstruction, the wait on getting a confirmation on the cross interrogate(XI) from the current owning processor 103 (CPy) delays this requestingprocessor 107 (CPx) from being able to start any storage update to theline A.

With the provision of a “demote” instruction, instead of having to takeup the delay on the XI acknowledgement, the SC 101 or 102 would havealready updated its directory to show that no processor currently ownsthe line exclusively, and thus can return the line A exclusively toprocessor 107 CPx when processor 107 CPx requests for it in a verytimely manner. This is shown in FIGS. 3 and 4.

In FIG. 3, when the application running in processor 103 CPy decides to“demote” the cache line, processor 103 CPy will send a demote request online A to SC0 101. Once the demote request is received, the SC0 101 willprocess the request as if a processor is requesting line A exclusive(even though no processor is actually requesting this). It will start upthe lookup in its directory, send a cross interrogate to processor 103CPy to request a release on exclusive rights. Processor 103 CPy at thistime should naturally be accepting the release request. Processor 103CPy will update its directory with no more exclusive rights and sendback an acknowledgement to SC0 101. Once the acknowledgement isreceived, the SC0 101 will update its directory update to indicate thatline A is now exclusive to “no one”. The software demote process is thusaccomplished.

Now, as seen in FIG. 4, if another processor 107 CPx requests line Aexclusive, the SC1 102 can quickly request the line exclusively from SC0101, and then reply to the requesting processor 107 CPx with anexclusive response without acquiring any delay for cross interrogationtowards processor 103 CPy. This reduction of delay could be even moreapparent in a system if the Storage Controllers 101, 102 are on adifferent chip(s) than the processors, where the cross-chipcommunication is now removed.

To further describe a variant implementation of this demote instruction,we will illustrate with a system where there is a private Level 2 cache(L2) per processor. This is shown in FIG. 5. Each processor 103-108 inthis system has a private L2 200.

In this design, when processor 103 CPy sends a demote request to itsprivate L2 200 L2y, the L2 will lookup its directory, and then send arelease exclusive cross interrogate back into the processor 103 CPy. TheLoad Store Unit (LSU) inside the processor 103 CPy will process theinterrogate request, remove its directory status of exclusive ownership,and acknowledge to L2 200 L2y that this is done.

This private L2 200 L2y will then also update its directory to indicateno exclusive ownership, and send a demote request to the SC0 101. Uponreceiving the demote request, SC0 101 will update its directory toindicate the line A is now exclusive to “no one”. With thisillustration, it will be appreciated that this function can beimplemented with various systems having a different cache hierarchy ortopology than that illustrated. Because these can be implemented bythose skilled in the art after learning of this teaching, all therevariants are not specifically shown.

A computer instruction executing on a processor practicing the presentinvention might employ any of a variety of cache line state mechanismsadvantageously including the well known MESI and MOESI snoop mechanisms.

According to the online Wikipedia, the free encyclopedia, ModifiedExclusive. Shared Invalidate (MESI) is as follows:

MESI: A cache may satisfy a read from any state except Invalid. AnInvalid line must be fetched (to the Shared or Exclusive states) tosatisfy a read.

A write may only be performed if the cache line is in the Modified orExclusive state. If it is in the Shared state, all other cached copiesmust be invalidated first. This is typically done by a broadcastoperation known as Read For Ownership (RFO).

A cache may discard a non-Modified line at any time, changing to theInvalid state. A Modified line must be written back first.

A cache that holds a line in the Modified State must snoop (intercept)all attempted reads (from all of the other CPUs in the system) of thecorresponding main memory location and insert the data that it holdsinto memory. This is typically done by forcing the read to back off(i.e. to abort the memory bus transaction), then writing the data tomain memory and changing the cache line to the Shared state.

A cache that holds a line in the Shared state must also snoop allinvalidate broadcasts from other CPUs, and discard the line (by movingit into Invalid state) on a match.

A cache that holds a line in the Exclusive state must also snoop allread transactions from all other CPUs, and move the line to Shared stateon a match.

The Modified and Exclusive states are always precise; i.e. they matchthe true cacheline ownership situation in the system. The Shared statemay be imprecise: if another CPU discards a Shared line, and this CPUbecomes the sole owner of that cacheline, the line wilt not be promotedto Exclusive state (because broadcasting all cacheline replacements fromalt CPUs is not practical over a broadcast snoop bus).

In that sense the Exclusive state is an opportunistic optimization: Ifdie CPU wants to modify a cache line that is in state S, a bustransaction is necessary to invalidate all other cached copies. State Eenables modifying a cache line with no bus transaction.

Read for Ownership:

A Read For Ownership (RfO) is an operation in CACHE COHERENCY protocols.The operation is issued by a processor trying to write into a cache linethat is not exclusive to itself, i.e., that is in the shared (S) orinvalid (I) states of the MESI protocol. The operation causes all otherprocessors to set the state of such line to I.

Also, according to the online Wikipedia, the free encyclopedia,Modified, Owned Exclusive, Shared Invalidate (MOESI) is as follows:

From Wikipedia, the free encyclopedia MOESI is a full CACHE COHERENCYprotocol that encompasses all of the possible states commonly used inother protocols. As discussed in AMD64 Architecture Programmer's ManualVol 2 ‘System Programming’, each CACHE LINE is in one of five states;

Modified: A cache line in the modified state holds the most recent,correct copy of the data. The copy in main memory is stale (incorrect),and no other processor holds a copy.

Owned: A cache line in the owned state holds the most recent, correctcopy of the data. The owned state is similar to the shared state in thatother processors can hold a copy of the most recent, correct data.Unlike the shared state, however, the copy in main memory can be stale(incorrect). Only one processor can hold the data in the owned state—allother processors must hold the data in the shared state.

Exclusive: A cache line in the exclusive state holds the most recent,correct copy of the data. The copy in main memory is also the mostrecent, correct copy of the data. No other processor holds a copy of thedata.

Shared; A cache line in the shared state holds the most recent, correctcopy of the data. Other processors in the system may hold copies of thedata in the shared state, as well. The copy in main memory is also themost recent, correct copy of the data, if no other processor holds it inowned state.

Invalid: A cache line in the invalid state docs not hold a valid copy ofthe data. Valid copies of the data can be either in main memory oranother processor cache.

This protocol, a more elaborate version of the simpler MESI protocol,avoids the need to write modifications back to main memory when anotherprocessor tries to read it. Instead, the owned state allows a processorto retain the right to modify a shared cache line by promising to shareany writes it performs with the other caches.

MOESI is beneficial when the communication latency and bandwidth betweentwo CPUs is significantly better than to main memory. Multi-core CPUswith per-core L2 caches are an example of that.

FIG. 6 illustrates how such an instruction is processed within amicroprocessor core. For this description, only 3 of the key units IDU301 (Instruction Dispatch Unit), FXU 302 (Fixed Point Unit), and LSU 303(Load Store Unit) are depicted as part of the microprocessor CP 300.

During hardware execution of this instruction, the microprocessorpipeline will execute this instruction as a 1 cycle superscalarinstruction that performs no architectural updates. All the work is tobe performed by the cache subsystem.

For an in-order microprocessor CP 300, when the “demote instruction” isdispatched from the instruction dispatch unit IDU 301, the logicaladdress calculated according to the instruction format and a decode ofsuch instruction indicating a demote operation will be sent from IDU 301to LSU 303 (arrow 1). In parallel, IDU 301 will send the opcode to FXU302 (arrow 2) which will complete the instruction if this is the next tocomplete without waiting for any acknowledgement or doing anyarchitectural update.

LSU 303 will obtain the absolute address used in cache management byeither looking up the address translation of the logical address sentfrom IDU 301 in its TLB 310, or obtain a translation result through adynamic translation process. Once the absolute address is obtained(arrow 4), it will arm the absolute address and a demote command in oneof its available Fetch Address Register (FAR) 312. The demote commandwill be a predefined interface value on the request bus (arrow 6) to theStorage Controller (SC) indicating a “demote” is to be performed.

The LSU's 303 control logic 313 will hold on to the demote request, andwait until all prior instructions complete before it send the demoterequest and address to the SC (arrow 6). This is done by monitoringpipeline flushing interface from the FXU 302 which controls instructioncompletion in this example. It is important that the demote request isnot sent under an incorrectly predicted branch path, or if any olderinstruction does not successfully complete due to processor pipelineflushing conditions. Otherwise, unnecessary performance penalty may beincurred.

In an out of order microprocessor, due to the nature of the design, theactual launch of the demote request from the LSU makes use of a tag. Tofit into an out of order design, the demote request sitting in the FARregister is tagged with an instruction ID, and only launched when theglobal completion logic determines that this instruction ID is beingcompleted.

An alternative design, not specifically shown in FIG. 5 but illustratedthereby, will have the demote request be written into a store queueentry (instead of a FAR register entry) at 312. By doing so, sincestores have to be completed and processed in order for machinesrequiring a strongly-ordered memory model, the store queue logic at 312can precisely send the demote request (through the FAR logic) withoutbeing premature.

In a mainframe, architected machine instructions are used by programmers(typically writing applications in “C” but also Java®, COBOL, PL/I,PL/X, Fortran and other high level languages), often by way of acompiler application. These instructions stored in the storage mediummay be executed natively in a z/Architecture IBM Server, oralternatively in machines executing other architectures. They can beemulated in the existing and in future IBM mainframe servers and onother machines of IBM (e.g. pSeries® Servers and xSerics® Servers). Theycan be executed in machines running Linux on a wide variety of machinesusing hardware manufactured by IBM®, Intel®, AMD™, Sun Microsystems andothers. Besides execution on that hardware under a z/Architecture®,Linux can be used as well as machines which use emulation by Hercules,UMX, FSI (Fundamental Software, Inc) or Platform Solutions, Inc. (PSI),where generally execution is in an emulation mode. In emulation mode,emulation software is executed by a native processor to emulate thearchitecture of an emulated processor.

The native processor typically executes emulation software comprisingeither firmware or a native operating system to perform emulation of theemulated processor. The emulation software is responsible for fetchingand executing instructions of the emulated processor architecture. Theemulation software maintains an emulated program counter to keep trackof instruction boundaries. The emulation software may fetch one or moreemulated machine instructions at a time and convert the one or moreemulated machine instructions to a corresponding group of native machineinstructions for execution by the native processor. These convertedinstructions may be cached such that a faster conversion can beaccomplished. Not withstanding, the emulation software must maintain thearchitecture rules of the emulated processor architecture so as toassure operating systems and applications written for the emulatedprocessor operate correctly. Furthermore the emulation software mustprovide resources identified by the emulated processor architectureincluding, but not limited to control registers, general purposeregisters (often including floating point registers), dynamic addresstranslation function including segment tables and page tables forexample, interrupt mechanisms, context switch mechanisms, Time of Day(TOD) clocks and architected interfaces to I/O subsystems such that anoperating system or an application program designed to run on theemulated processor, can be run on the native processor having theemulation software.

A specific instruction being emulated is decoded, and a subroutinecalled to perform the function of the individual instruction. Anemulation software function emulating a function of an emulatedprocessor is implemented, for example, in a “C” subroutine or driver, orsome other method of providing a driver for the specific hardware aswill be within the skill of those in the art after understanding thedescription of the preferred embodiment. Various software and hardwareemulation patents including, but not limited to U.S. Pat. No. 5,551,013for a “Multiprocessor for hardware emulation” of Bcausoleil et al., andU.S. Pat. No. 6,009,261: Preprocessing of stored target routines foremulating incompatible instructions on a target processor” of Scalzi etal; and U.S. Pat. No. 5,574,873: Decoding guest instruction to directlyaccess emulation routines that emulate the guest instructions, ofDavidian et al; U.S. Pat. No. 6,308,255: Symmetrical multiprocessing busand chipset used for coprocessor support allowing non-native code to runin a system, of Gorishek et al; and U.S. Pat. No. 6,463,582: Dynamicoptimizing object code translator for architecture emulation and dynamicoptimizing object code translation method of Lethin el al; and U.S. Pat.No. 5,790,825: Method for emulating guest instructions on a hostcomputer through dynamic recompilation of host instructions of EricTraut; and many others, illustrate the a variety of known ways toachieve emulation of an instruction format architected for a differentmachine for a target machine available to those skilled in the art, aswell as those commercial software techniques used by those referencedabove.

Referring to FiG. 7, representative components of a Host Computer system700 are portrayed. Other arrangements of components may also be employedin a computer system which are well known in the art. The representativeHost Computer 700 comprises one or more CPUs 701 in communication withmain store (Computer Memory 702) as well as I/O interfaces to storagedevices 707 and networks 701 for communicating with other computers orSANs and the like. The CPU may have Dynamic Address Translation (DAT)703 for transforming program addresses (virtual addresses) into realaddress of memory. A DAT typically includes a Translation LookasideBuffer (TLB) 707 for caching translations so that later access to theblock of computer memory 702 do not require the delay of addresstranslation. Typically a cache 709 is employed between Computer Memory702 and the Processor 701. the cache 709 may be hierarchical having alarge cache available to more than one CPU and smaller, faster (lowerlevel) caches between the large cache and each CPU. In someimplementations the lower level caches are split to provide separate lowlevel caches for instruction fetching and data accesses. In anembodiment, an instruction is fetched from memory 702 by an instructionfetch unit 704 via a cache 709. The instruction is decoded in aninstruction decode unit (706) and dispatched (with other instructions insome embodiments) to instruction execution units 708. Typically severalexecution units 708 are employed, for example an arithmetic executionunit, a floating point execution unit and a branch instruction executionunit. The instruction is executed by the execution unit, accessingoperands from instruction specified registers or memory as needed. If anoperand is to be accessed (loaded or stored) from memory 702, a loadstore unit 705 typically handles the access under control of theinstruction being executed.

Software programming code which embodies the present invention istypically accessed by the processor also known as a CPU (CentralProcessing Unit) 701 of the system 700 from long-term storage media 707,such as a CD-ROM drive, tape drive or hard drive. The softwareprogramming code may be embodied on any of a variety of known media foruse with a data processing system, such as a diskette, hard drive, orCD-ROM. The code may be distributed on such media, or may be distributedto users from the computer memory 702 or storage of one computer systemover a network 710 to other computer systems for use by users of suchother systems.

Alternatively, the programming code may be embodied in the memory 702,and accessed by the processor 701 using the processor bus. Suchprogramming code includes an operating system which controls thefunction and interaction of the various computer components and one ormore application programs. Program code is normally paged from densestorage media 707 to high-speed memory 702 where it is available forprocessing by the processor 701. The techniques and methods forembodying software programming code in memory, on physical media, and/ordistributing software code via networks are well known and will not befurther discussed herein. Program code, when created and stored on atangible medium (including but not limited to electronic memory modules(RAM), flash memory, Compact Discs (CDs), DVDs, Magnetic Tape and thelike is often referred to as a “computer program product”. The computerprogram product medium is typically readable by a processing circuitpreferably in a computer system for execution by the processing circuit.

In FIG. 5, an example emulated Host Computer system 801 is provided thatemulates a Host computer system 700 of a Host architecture. In theemulated Host Computer system 801, the host processor (CPUs) 808 is anemulated Host processor (or virtual Host processor) and comprises anemulation processor 807 having a different native instruction setarchitecture than that of used by the processor 701 of the Host Computer700. The emulated Host Computer system 801 has memory 802 accessible tothe emulation processor 807. In the example embodiment, the Memory 807is partitioned into a Host Computer Memory 702 portion and an EmulationRoutines 803 portion. The Host Computer Memory 702 is available toprograms of the emulated Host Computer 801 according to Host ComputerArchitecture. The emulation Processor 807 executes native instructionsof an architected instruction set of an architecture other than that ofthe emulated processor 808, the native instructions obtained fromEmulation Routines memory 803, and may access a host instruction forexecution from a program in Host Computer Memory 702 by employing one ormore instruction(s) obtained in a Sequence & Access/Decode routine whichmay decode the host instruction(s) accessed to determine a nativeinstruction execution routine for emulating the function of the hostinstruction accessed. Other facilities that are defined for the HostComputer System 700 architecture may be emulated by ArchitectedFacilities Routines, including such facilities as General PurposeRegisters, Control Registers, Dynamic Address Translation and I/OSubsystem support and processor cache for example. The EmulationRoutines may also take advantage of function available in the emulationProcessor 807 (such as general registers and dynamic translation ofvirtual addresses) to improve performance of the Emulation Routines.Special Hardware and Off-Load Engines may also be provided to assist theprocessor 807 in emulating the function of the Host Computer 700.

The present invention provides prefetch data instructions forprefetching a line of data to cache and for modifying the owner shiplevel of a line of data in the cache. When a PREFETCH DATA instructionFIG. 9 (comprising any of a PREFETCH DATA instruction and a PREFETCHDATA RELATIVE LONG instruction) is fetched FIG. 10 1001 and executed bya processor 701 or CPU (Central Processing Unit), subject to thecontrols specified in the M field of the instruction, the CPU 701interprets 1002 the M field to determine what function 1003 is to beperformed by the PREFETCH DATA instruction. Either the CPU function isto prefetch the second operand from memory 702 into a cache line of acache 1005 1006, or it is to release a cache line containing the secondoperand. The second operand designates a logical address which is theaddress to memory that the program uses, a logical address (sometimescalled a virtual address) that is subject to Dynamic Address Translation(DAT) in some embodiments.

Preferably the cache 709 comprises only a single L1 cache 1006 or both aL1 cache 1006 and a higher level L2 Cache. Cache controls 1007responsible for manipulating the cache data also manipulate cachecoherency protocols (XI, MESI or MEOSI) in order to perform thepre-fetch of the cache line into a cache (and evict a previous line tomake room for the prefetched line) and to manage the cache ownershipprotocol (cache coherency) with caches of other processors sharing amemory subsystem.

The cache controls 1007 will ascertain first whether the line is alreadyin one of the caches and will prefetch the line into one of the cachesfrom memory if needed. The cache controls 1007 will also manipulate thecache ownership according to the function 1003 identified by the M field1002. A cache ownership of Store indicates to the processor that storeis permitted to the cache line as by the processor so the processor“owns” the cache line to be able to store into it. A cache ownership offetch indicates the processor is permitted to fetch from the cache linebut not to store (modify) it. A cache ownership of release in oneembodiment indicates that the cache may invalidate the line (evict it).

In an embodiment, a PREFETCH DATA (PFD) instruction comprises an opcode“E3” in bits 0-7, an M1 field in bits 8-11, an X2 field in bits 12-15, aB2 field in bits 16-19, a displacement field low order DL2 in bits20-31, a displacement field high order DH2 in bits 32-39 and an opcodeextension “36” in bits 40-47. In order to generate a logical address ofa second operand in memory, the signed displacement represented by DH∥DL(sign extended for 2's complement) is algebraically added to a value ina register designated by the B2 field. If the X2 field is not zero, thevalue in the register designated by the X2 field is added as well.

In an embodiment, a PREFETCH DATA RELATIVE LONG (PFDRL) instructioncomprises an opcode “C6” in bits 0-7, an M1 field in bits 8-11, anextended opcode in bits 12-15 and on immediate field I2 in bits 16-47.The address of the second operand is obtained by algebraically addingthe signed I2 field (sign extended for 2's complement) to the programcounter value (the program counter value is preferably pointing to thePFDRL being executed.

The M1 field contains a 4-bit unsigned binary integer that is used as acode to signal the CPU as to the intended use of the second operand. Thecodes are as follows:

Code Function Performed 1 Prefetch the line of data at thesecond-operand address to the CPU cache for fetch access ownership. 2Prefetch the line of data at the second-operand address to the CPU cachefor store access ownership. 3 Conditionally prefetch the line of data atthe second operand to the CPU cache for possible store access. The CPUwill attempt to prefetch the cache line to have store access ownershipto it, but if the line is not available for store access ownership, theCPU can prefetch the line for fetch access ownership. 6 Release thecache line in the CPU cache from store access ownership. The cache linecontaining the second operand; retain the data in the cache line forfetch access ownership 7 Release the cache line in the CPU cache fromall access owner- ship. The cache line containing the second operand

Other codes are possible including those supporting MESI and MOESIcoherency caches. For example, codes might be employed to release acache line from any of the MOESI or MESI states explicitly or accordingto a priority scheme for example. In an embodiment, certain MESI orMOESI ownership states may only be accessed when executing a privilegedversion of an instruction or when executing in a privileged (supervisor)mode.

Depending on the implementation, the CPU may not implement all of theprefetch functions. Preferably, for functions that are not implementedby the CPU, and for reserved functions, the instruction acts as a no-op.Code 0 preferably always acts as a no-op.

Preferably, no access exceptions or Program Event Recording (PER)storage-alteration exceptions are recognized for the second operand. Inone embodiment, for codes 2 and 3, it is unpredictable whether thechange bit is set for the second operand. The change bit is a bitassociated with a page of storage that indicates whether the page hasbeen modified, in which case it must be returned to non-volatile Store(DASD) when being “paged out” of memory (storage). For all codes, a TLBentry may be formed for the data that is prefetched. For PREFETCH DATA,the displacement field of the instruction is treated as a 20-bit signed

For the PREFETCH DATA RELATIVE LONG instruction, the contents of the I2field are signed binary integer specifying the number of halfwords thatis to be added to the address of the instruction (program counteraddress) to generate the address of the second operand. When the CPU isin certain modes, for example, the 2/Architecture primary-space,secondary-space or access-register modes, the second operand is assumedto be in a predetermined mode (the z/Architecture primary address spacefor example). When the CPU is in the z/Architecture home-space mode, thesecond operand is assumed to be in the z/Architecture home addressspace.

An Operation exception may be encountered if the instruction facilitysupporting the instruction (the z/Architecturegeneral-instructions-extension facility) is not installed. An Operationexception would cause a context switch, passing the CPU to a program forhandling Operation exceptions.

A Prefetch DATA instruction or a PREFETCH DATA (RELATIVE LONG)instruction, when executed, preferably signals the CPU to perform thespecified operation, but it does not guarantee that the CPU willnecessarily honor the request. In an embodiment, there is no guaranteethat storage location will still be in the cache when a subsequentinstruction references the location. Likewise, in the embodiment, thereis no guarantee that when a cache line is released that the CPU will notsubsequently refetch it (independent of any prefetching operations).Rather, the PREFETCH DATA (RELATIVE LONG) instruction simply provideshints as to the program's anticipated use of storage areas for suchembodiments. If an exception condition would otherwise be recognizedwhen accessing the second operand, PREFETCH DATA (RELATIVE LONG) ispreferably completed widi no indication of the exception provided to theprogram, however, the performance of the PREFETCH DATA (RELATIVE LONG)instruction may be significantly slower than if the exception conditiondid not exist. In an embodiment, significant delay may be experienced ifa storage location has been prefetched and then released, and then asubsequent instruction references the same storage location. Similarly,a delay may be experienced if a storage location has been prefetched forfetch access ownership, and then a subsequent instruction references thesame location for storing. In CPUs that implement separate data andinstruction caches, the use of codes 2 or 3 to prefetch (for storing) acache line from which instructions will subsequently be fetched maycause significant delays in some embodiments. Similar delays may beexperienced for any store operation into a cache line from whichinstructions are subsequently fetched. The use of PREFETCH DATA(RELATIVE LONG) instructions to prefetch operands that are frequentlyupdated in a multiprocessing environment may actually degradeperformance by causing unnecessary contention for the cache line. Aprefetch operation preferably consists of fetching a cache line on anintegral boundary. The cache line size (and corresponding integralboundary) may be determined by executing an EXTRACT CACHE ATTRIBUTEinstruction for example. The second operand is preferably fetched intothe cache line in predetermined units that may differ between models ofCPUs, on an integral boundary, the minimum size of which is preferably adouble word. Thus, preferably at least the rightmost three bits of thesecond-operand address are assumed to contain zeros, regardless of whatis specified by the program. Preferably, the unit directly addressed bythe second-operand address is prefetched first. The order in which theremaining units of the cache line are prefetched is also implementationdependent.

As frustrated, the present invention can help improve system performanceby carefully inserting “demote” instructions in software code, with ahardware provision of such mechanism. It requires thoughtfulimplementation in software, firmware, together with hardware to beeffective.

The flow diagrams depicted herein are just examples. There may be manyvariations to these diagrams or the steps (or operations) describedtherein without departing from the spirit of the invention. Forinstance, the steps may be performed in a differing order, or steps maybe added, deleted or modified. All of these variations are considered apart of the claimed invention.

While the preferred embodiment to the invention has been described, itwilt be understood that those skilled in the art, both now and in thefuture, may make various improvements and enhancements which fall withinthe scope of the claims which follow. These claims should be construedto maintain the proper protection for the invention first described.

1. A computer program product for executing a prefetch data machineinstruction, the computer program product comprising: a storage mediumreadable by a processing circuit and storing instructions for executionby the processing circuit of a processor for performing a methodcomprising: the processor fetching the prefetch data machineinstruction, the prefetch data machine instruction comprising an opcodefield, the opcode field specifying the prefetch data machineinstruction; and the processor executing the fetched prefetch datamachine instruction adapted to either prefetch data to the cache orchange access ownership of a cache line in the cache, the executingcomprising: determining whether to perform a data prefetch cache actionor a cache line ownership operation, the data prefetch cache action forprefetching a cache line of data from, memory to the cache, the cacheline ownership operation for changing cache access ownership of a lineof data in the cache; determining an address of an operand in memory;and responsive to determining to perform the cache line ownershipoperation, performing a determined cache action on a cache line in thecache, the cache line associated with the determined address of theoperand, the cache action comprising: responsive to the determined cacheaction being a release store access ownership action, changing accessownership of the cache line to a fetch access ownership, the storeaccess ownership indicating that the processor intends to store to thecache line, the fetch access ownership indicating that the processorintends to fetch data from the cache line; and responsive to thedetermined cache action being a release fetch access ownership action,releasing access ownership, the released access ownership indicatingthat the processor does not intend to access to the cache line.
 2. Theprogram product according to claim 1, wherein the store access ownershipindicates the cache line is not available to other processors, andwherein the fetch access ownership indicates the cadre line may beshared by other processors.
 3. The program product according to claim 1,the further comprising: responsive to the determined cache action beinga modified access ownership action, changing access ownership of thecache line to indicate the cache line has been modified; and responsiveto the determined cache action being an owned access ownership action,changing access ownership of the cache line to indicate the cache lineis owned.
 4. The method according to claim 2, wherein the prefetch datamachine instruction further comprises an option field and operandinformation, wherein the function of the prefetch data machineinstruction further comprises: interpreting the option field todetermine whether to perform the data prefetch cache action or the cacheline ownership operation; determining from said operand information, theaddress of the operand; and responsive to the determined cache actionbeing a data prefetch action, prefetching said operand into said cacheline of said cache.
 5. The program product according to claim 4, whereinthe cache action comprises: responsive to the option field being a firstvalue, performing no cache action; responsive to the option field beinga second value, prefetching to the cache, data specified by the operandaddress for fetch access ownership wherein the cache line accessownership is set as fetch access ownership; and responsive to the optionfield being a third value, prefetching to the cache, data specified bythe operand address for store access ownership wherein the cache lineaccess ownership is set as store access ownership.
 6. The programproduct according to claim 4, wherein the cache action comprises:responsive to the option field being a fourth value and store accessownership being available, prefetching to the cache, data specified bythe operand address for store access ownership wherein the cache lineaccess ownership is set as store access ownership; and responsive to theoption field being the fourth value and store access ownership beingnot-available, prefetching to the cache, data specified by the operandaddress for store access ownership wherein the cache line accessownership is set as fetch access ownership.
 7. The program productaccording to claim 1, wherein the prefetch data machine instructionfurther comprises a signed immediate field, wherein the address of theoperand in memory is related to a memory address of the prefetchinstruction being executed, comprising adding a halfword aligned signextended value of the signed immediate field of the instruction to aprogram address of the prefetch data instruction being executed todetermine the address of the operand in memory.
 8. The program productaccording to claim 1, wherein access ownership is either MESI or MOESIprotocol, wherein said cache line is resident in a cache of a processorexecuting the instruction, said cache action comprising any one of;changing cache ownership from modified to any one of owned, exclusive,shared or invalid, changing cache ownership from owned to any one ofmodified, exclusive, shared or invalid, changing cache ownership fromexclusive to any one of modified, owned, shared or invalid, or changingcache ownership from shared to any one of modified, owned, exclusive orinvalid.
 9. The computer program product according to claim 1, furthercomprising interpreting the prefetch data machine instruction toidentify a predetermined software routine for emulating operation of theprefetch data machine instruction; and wherein the executing theprefetch data machine instruction comprises executing the predeterminedsoftware routine to execute the prefetch data machine instruction.
 10. Acomputer system for executing a prefetch data machine instruction, thesystem comprising: a memory; a cache in communication with the memory;and a processor in communication with the cache and the memory, theprocessor comprising an instruction fetching unit for accessinginstructions from memory and one or more execution units for executingaccessed instructions; wherein the processor performs a methodcomprising: fetching the prefetch data machine instruction, the prefetchdata machine instruction comprising an opcode field, the opcode fieldspecifying the prefetch data machine instruction; and executing thefetched prefetch data machine instruction adapted to either prefetchdata to the cache or change access ownership of a cache line in thecache, the executing comprising: determining whether to perform a dataprefetch cache action or a cache line ownership operation, the dataprefetch cache action for prefetching a cache line of data from memoryto the cache, the cache line ownership operation for changing cacheaccess ownership of a line of data in the cache; determining an addressof an operand in memory; and responsive to determining to perform thecache line ownership operation, performing a determined cache action ona cache line in the cache, the cache line associated with the determinedaddress of the operand, the cache action comprising: responsive to thedetermined cache action being a release store access ownership action,changing access ownership of the cache line to a fetch access ownership,the store access ownership indicating that the processor intends tostore to the cache line, the fetch access ownership indicating that theprocessor intends to fetch data from the cache line; and responsive tothe determined cache action being a release retch access ownershipaction, releasing access ownership, the released access ownershipindicating that the processor does not intend to access to the cacheline.
 11. The computer system according to claim 10, wherein the storeaccess ownership indicates the cache line is not available to otherprocessors, and wherein the fetch access ownership indicates the cacheline may be shared by other processors.
 12. The computer systemaccording to claim 10, the further comprising: responsive to thedetermined cache action being a modified access ownership action,changing access ownership of the cache line to indicate the cache linehas been modified; and responsive to the determined cache action beingan owned access ownership action, changing access ownership of the cacheline to indicate the cache line is owned.
 13. The computer systemaccording to claim 11, wherein the prefetch data machine instructionfurther comprises an option field and operand information, wherein thefunction of the prefetch data machine instruction further comprises:interpreting the option field to determine whether to perform the dataprefetch cache action or the cache line ownership operation; determiningfrom said operand information, the address of the operand; andresponsive to the determined cache action being a data prefetch action,prefetching said operand into said cache line of said cache.
 14. Thecomputer system according to claim 13, wherein the cache actioncomprises: responsive to the option field being a first value,performing no cache action; responsive to the option field being asecond value, prefetching to the cache, data specified by the operandaddress for fetch access ownership wherein the cache line accessownership is set as fetch access ownership; and responsive to the optionfield being a third value, prefetching to the cache, data specified bythe operand address for store access ownership wherein the cache lineaccess ownership is set as store access ownership.
 15. The computersystem according to claim 13, wherein the cache action comprise:responsive to the option field being a fourth value and store accessownership being available, prefetching to the cache, data specified bythe operand address for store access ownership wherein the cache lineaccess ownership is set as store access ownership; and responsive to theoption field being the fourth value and store access ownership beingnot-available, prefetching to the cache, data specified by the operandaddress for store access ownership wherein the cache line accessownership is set as fetch access ownership
 16. The computer systemaccording to claim 10, wherein the prefetch data machine instructionfurther comprises a signed immediate field, wherein the address of theOperand in memory is related to a memory address of the prefetchinstruction being executed, comprising adding a halfword aligned signextended value of the signed immediate field of the instruction to aprogram address of the prefetch data instruction being executed todetermine the address of the operand in memory.
 17. The computer systemaccording to claim 10, wherein access ownership is either MESI or MOESIprotocol, wherein said cache line is resident in a cache of a processorexecuting the instruction, said cache action comprising any one of:changing cache ownership from modified to any one of owned, exclusive,shared or invalid, changing cache ownership from owned to any one ofmodified, exclusive, shared or invalid, changing cache ownership fromexclusive to any one of modified, owned, shared or invalid, or changingcache ownership from shared to any one of modified, owned, exclusive orinvalid.
 18. The computer program product according to claim 10, furthercomprising interpreting the prefetch data machine instruction toidentify a predetermined software routine for emulating operation of theprefetch data machine instruction; and wherein the executing theprefetch data machine instruction comprises executing the predeterminedsoftware routine to execute the prefetch data machine instruction. 19.In a computer system having a processor, wherein the processor isassociated with a cache for caching, cache lines of memory information,a method for executing a prefetch data machine instruction of a program,the method comprising: fetching the prefetch data machine instruction,the prefetch data machine instruction comprising an opcode field, theopcode field specifying the prefetch data machine instruction; andexecuting the fetched prefetch data machine instruction adapted toeither prefetch data to the cache or change access ownership of a cacheline in the cache, the executing comprising: determining whether toperform a data prefetch cache action or a cache line ownershipoperation, the data prefetch cache action for prefetching a cache lineof data from memory to the cache, the cache line ownership operation forchanging cache access ownership of a line of data in the cache;determining an address of an operand in memory; and responsive todetermining to perform the cache line ownership operation, performing adetermined cache action on a cache line in the cache, the cache lineassociated with the determined address of the operand, the cache actioncomprising: responsive to the determined cache action being a releasestore access ownership action, changing access ownership of the cacheline to a fetch access ownership, the store access ownership indicatingthat the processor intends to store to the cache line, the fetch accessownership indicating that the processor intends to fetch data from thecache line; and responsive to the determined cache action being arelease fetch access ownership action, releasing access ownership, thereleased access ownership indicating that the processor does not intendto access to the cache line.
 20. The method according to claim 19,wherein the store access ownership indicates the cache line is notavailable to other processors, and wherein the fetch access ownershipindicates the cache line may be shared by other processors.
 21. Themethod according to claim 19, wherein the prefetch, data machineinstruction further comprises an option field and operand information,wherein the function of the prefetch data machine instruction furthercomprises: interpreting the option field to determine whether to performthe data prefetch cache action or the cache line ownership operation;determining from said operand information, the address of the operand;and responsive to the determined cache action being a data prefetchaction, prefetching said operand into said cache line of said cache. 22.The method according to claim 21, wherein the cache action comprises:responsive to the option field being a first value, performing no cacheaction; responsive to the option field being a second value, prefetchingto the cache, data specified by the operand address for fetch accessownership wherein the cache line access ownership is set as fetch accessownership; and responsive to the option field being a third value,prefetching to the cache, data specified by the operand address forstore access ownership wherein the cache line access ownership is set asstore access ownership.
 23. The method according to claim 21, whereinthe cache action comprises: responsive to the option field being afourth value and store access ownership being available, prefetching tothe cache, data specified by the operand address for store accessownership wherein the cache line access ownership is set as store accessownership; and responsive to the option field being the fourth value andstore access ownership being not-available, prefetching to the cache,data specified by the operand address for store access ownership whereinthe cache line access ownership is set as fetch access ownership. 24.The method according to claim 19, wherein the prefetch data machineinstruction further comprises a signed immediate field, wherein theaddress of the operand in memory is related to a memory address of theprefetch instruction being executed, comprising adding a halfwordaligned sign extended value of the signed immediate field of theinstruction to a program address of the prefetch data instruction beingexecuted to determine the address of the operand in memory.
 25. Themethod according to claim 19, further comprising interpreting theprefetch data machine instruction to identify a predetermined softwareroutine for emulating operation of the prefetch data machineinstruction; and wherein the executing the prefetch data machineinstruction comprises executing the predetermined software routine toexecute the prefetch data machine instruction.